JP2004102063A - Image display device, its control method and multi-display system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a multi-display system without needing a display control signal for multi-display from the outside, and to provide an image display method. <P>SOLUTION: The image display device 200 is equipped with interfaces (201, 208) for inputting image data and outputting downstream, a DDC communication processing part 207, and a rewritable memory 206 for storing EDID information. If the image display device is connected to the downstream end, the EDID information is acquired from an image display device connected through the DDC communication processing part 207, setting display resolution information and interconnection information for example. Particularly, the items of the display resolution in the EDID information are rewritable by the display resolution information set as above. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image display device, and more particularly to an image display device suitable for a multi-display system that displays a combination of a plurality of image display devices and a control method thereof.
[0002]
[Prior art]
In recent years, a dot matrix type device represented by a liquid crystal display, a plasma display, or the like has been used as an image display device of a computer device or the like. Since these devices have a fixed number of display pixels, it is necessary to perform a so-called resolution conversion process of optimizing the resolution (the number of display pixels) of the input image signal in accordance with the number of pixels of the device.
[0003]
FIG. 12 is a functional block diagram of a general image display device that performs a resolution conversion process. In FIG. 1, reference numeral 100 denotes an image output device that outputs an image signal, and 200 denotes an image display device. The image display device 200 includes an image input I / F 201, a resolution conversion unit 202, a display device driving unit 203, a control unit 204, and a display device 205.
[0004]
In this configuration, the image signal output from the image output device 100 is input to the image input I / F 201 of the image display device 200. The image input I / F 201 performs A / D conversion processing when the image signal input from the image output device 100 is, for example, an analog signal, and outputs a digital signal to the resolution conversion unit 202. Alternatively, for example, in the case of a digital transmission signal conforming to a digital signal transmission standard represented by TMDS, the image input I / F 201 outputs a digital signal to the resolution conversion unit 202 via a receiver.
[0005]
In the resolution conversion unit 202, for example, when the display resolution of the display device 205 is XGA (1024 × 768 pixels) and the resolution of the input image signal is lower than the resolution of the display device 205 and SVGA (800 × 600 pixels) The number of horizontal and vertical pixels of the input image signal is enlarged by 1.28 times to generate an image display signal that matches the number of pixels of the display device 205. Conversely, when the resolution of the input image signal is higher than the resolution of the display device 205, for example, UXGA (1600 × 1200 pixels), the number of horizontal and vertical pixels of the input image signal is reduced to 0.64 times, respectively. Then, an image display signal corresponding to the number of pixels of the display device 205 is generated.
[0006]
The control unit 204 controls the enlargement / reduction processing and the like. The display device drive unit 203 displays an image on the display device 205 using the image display signal generated by the resolution conversion unit 202.
[0007]
Also, as is generally known, recent personal computer operating systems (hereinafter referred to as OS) include a so-called plug which automatically sets image output from a computer so that an appropriate display is performed when a display is connected to the computer. And display function is provided. In order to realize this function, the image display device compatible with the plug-and-display function stores in advance a display-related attribute information in a memory (for example, 206 in FIG. 12), and the computer executes the DDC communication function (Display Data Channel) : The use of video signals is extended, and this attribute information is acquired using an extended interface specification that allows information to be transmitted from the display side to the host to obtain the optimal image signal output for the connected display. Do. This attribute information is EDID information (Extended Display Identification Data: a specification for transmitting display information from the display side to the host side, which defines a data format for transmitting the display capability to the host). And includes, for example, the resolution of the image display device, the frequencies of the horizontal and vertical scanning signals, and the like. Therefore, if the image display device is compatible with the plug-and-display function and the resolution of the display device is described as the EDID information, an image signal having a resolution optimal for display on the display can be obtained from a computer (image output device). .
[0008]
By the way, there is a so-called multi-display system in which a plurality of image display devices are arranged in, for example, M × N columns to display one image. This system is an image display device that is required to display large screens at exhibitions and advertising towers, because it has the advantages of being easy to compose a large screen, having a shorter depth than a large screen display by itself, and being able to increase relative brightness. It is used for In addition, it can be said that the image display method using the multi-display system is a technique for forming one high-resolution display device by combining low-resolution display devices.
[0009]
As a known example, for example, Patent Document 1 is disclosed. This conventional multi-display system will be described with reference to FIG.
[0010]
In FIG. 13, reference numeral 1001 denotes a multi-display interface circuit corresponding to a display control device, and 1002 denotes a display device. , -N indicate that there are a plurality of multi-display interface circuits 1001 and a plurality of display devices 1002. The multi-display interface circuit 1001 includes an input data processing circuit 1004, a data output unit, a control data processing circuit 1031, and a control unit.
[0011]
The data output unit includes a frame memory writing circuit 1007, a frame memory reading circuit 1008, a data selector 1009, frame memories 1010 and 1011, and an enlarged data processing circuit 1012. Further, the control unit includes a horizontal write start position register 1017, a horizontal write width register 1018, a vertical write start position register 1019, a vertical write width register 1020, an enlargement ratio setting register 1021, 1022, a horizontal read position register 1023, and a vertical read position register. 1024, a horizontal synchronization register 1025, a vertical synchronization register 1026, an output timing signal generation circuit 1014, a microcomputer 1028, an ID setting circuit 1029, and a data storage memory 1030.
[0012]
Image data transferred from the image output device is written to the frame memory 1010 or 1011 included in the data output unit via the input data processing circuit 1004. Here, the area where the image data is written to the frame memory 1010 or 1011 is controlled by the horizontal and vertical write start position registers 1017 and 1019 and the horizontal and vertical write width registers 1018 and 1020 included in the control unit. Next, the image data read from the frame memory 1010 or 1011 is subjected to enlargement processing and transferred to the display device 1002.
[0013]
The microcomputer 1028 of the control unit receives the command included in the control data transferred from the control bus, and expands the data stored in the data storage memory 1030 to each of the registers 1017 to 1026 of the control unit. This command specifies partial display data, and specifies a portion to be displayed on the corresponding display device 1002-n (n = 1, 2,...) From input image data. At this time, an ID number may be added to a command transferred as control data. The ID number has a role of instructing which display interface circuit 1001 among the respective display interface circuits constituting the multi-display to execute the command. In this case, the microcomputer 1028 compares the ID setting value set in the ID setting circuit 1029 with the ID number attached to the instruction, and executes the instruction when they match.
[0014]
In this way, the same image data is input to a plurality of display interface circuits constituting a multi-display, and display data of different areas is determined based on control data specifying a display area to be displayed on each display interface circuit. We are building a multi-display system to capture and display.
[0015]
[Patent Document 1]
JP 2000-148080 A
[0016]
[Problems to be solved by the invention]
At present, as a personal computer as an image signal source for transmitting an image signal, a personal computer capable of outputting a high-resolution signal of about QXGA (2048 × 1536 pixels) has been commercialized. Image display devices for displaying images are required to have the same display capability. By the way, in an image display apparatus using a conventional dot matrix type display device, even if a high resolution image signal is displayed, the resolution of the original image cannot be fully utilized because the resolution of the display device is low. In order to take full advantage of the resolution of the original image, it is generally considered to increase the number of pixels of the display device.However, developing such a display device is costly and increases the load on the control processing unit. there were.
[0017]
As a solution to this, a multi-display system using a plurality of display devices can be considered as disclosed in Patent Document 1. However, in a conventional multi-display system, image signals are allocated to a plurality of display devices together with image signals. It was necessary to input the display control signal of
[0018]
The present invention has been made in view of the above problems, and has as its object to provide an image display device and a control method thereof that can easily configure a multi-display system.
It is another object of the present invention to automatically notify a host of an optimum resolution according to the arrangement state of a display device in a multi-display system.
It is another object of the present invention to provide a multi-display system and an image display method that do not require an external display control signal for a multi-display.
[0019]
[Means for Solving the Problems]
An image display device according to the present invention for achieving the above object has the following configuration. That is,
An image display device having an image display unit,
Input / output means for inputting image data from a device connected on the upstream side and outputting the image data to a device connected on the downstream side,
When a display device is connected to the downstream side, an obtaining unit that obtains resolution information from the display device,
Generating means for generating resolution information based on the resolution information obtained by the obtaining means and the resolution of the image display unit,
A first holding unit for holding the generated resolution information so as to be notified to an upstream side.
Here, preferably, communication processing means for performing DDC communication with an external device,
A memory for storing EDID information communicated by the DDC communication,
The obtaining means obtains resolution information using the communication processing means,
The holding unit rewrites the generated resolution information as a corresponding item of EDID information in the memory.
[0020]
Further, preferably, when a display device is connected to at least one of the upstream side or the downstream side, determining means for determining the position of the display device in a multi-display formed by all connected display devices,
Determining means for determining an image range to be displayed by the image display unit based on the position determined by the determining means;
A display control unit for displaying, on the image display unit, an image range determined by the determination unit from the image data input by the input / output unit.
[0021]
In addition, a multi-display system according to the present invention that achieves the above object has a structure in which a plurality of the image display devices are connected, and a host computer is connected upstream of the most upstream image display device.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.
[0023]
<First embodiment>
FIG. 1 is a block diagram illustrating a configuration of the image forming apparatus according to the first embodiment. In FIG. 1, reference numeral 200 denotes an image display device, which is an image input I / F 201 to which image data is input from an image output device 100 (hereinafter, a personal computer), and a resolution for optimizing the resolution of the input image data to the resolution of the display device. A conversion unit 202, a display device driving unit 203 that generates an image display signal or the like to a display device, a control unit 204 that controls the entire image display device, a display device 205, a rewritable memory 206 that stores EDID information, and external devices. It includes a DDC communication processing unit 207 for performing DDC communication and an image output I / F 208 for outputting image data to the outside. In the present embodiment, the subscripts 1 and 2 indicate that there are two image display devices according to the present invention.
[0024]
In the configuration shown in FIG. 1, image data transmitted from the personal computer 100 is input to the image display device 200 via the image input I / F 201. The input image data may be an analog signal or a digital signal. When the input image data is an analog signal, the image input I / F 201 includes an A / D conversion circuit, digitizes it at a sampling timing optimal for the input image signal, and outputs the digital data to the resolution conversion unit 202 as digital data. When the input image data is a digital transmission signal conforming to a digital transmission standard represented by the TMDS standard, the image input I / F 21 receives the image data with a receiver that conforms to the standard, and converts the resolution into a digital signal. Output to conversion section 202.
[0025]
Further, the control unit 204 determines the resolution of the input image data from the horizontal and vertical synchronization signals included in the image data input to the image input I / F 201.
[0026]
The resolution conversion unit 202 performs enlargement or reduction processing so that the resolution of the input image data matches the number of pixels of the display device 205. For example, when the number of pixels included in the display device 205 is SVGA (800 × 600) and the resolution of the input image data (the resolution determined by the control unit 204) is VGA (640 × 480), the resolution conversion unit 202 The number of horizontal and vertical pixels of the image signal is each increased by 1.25 times to generate an image display signal that matches the number of pixels of the display device 205. Conversely, if the resolution of the input image signal is higher than the resolution of the display device 205, for example, UXGA (1600 × 1200 pixels), the resolution conversion unit 202 determines the number of horizontal and vertical pixels of the input image signal, respectively. An image display signal that is reduced by 0.5 times and matches the number of pixels of the display device 205 is generated.
[0027]
The control unit 204 performs control such as the above-described enlargement / reduction processing by the resolution conversion unit 202, determination of the resolution of input image data, and control such as DDC communication processing described later. The display device drive unit 203 displays an image on the display device 205 using the image display signal generated by the resolution conversion unit 202.
[0028]
The image output I / F 208 is for transferring the input image data to the next stage, and may be an analog signal or a digital signal according to the input. If the input image data is an analog signal, it is buffered and output, and if it is a digital signal, it is output as a digital transmission signal by a transceiver conforming to a digital transmission standard represented by the TMDS standard, for example.
[0029]
FIG. 2 is a detailed block diagram illustrating an example of the resolution conversion unit 202. In FIG. 2, reference numeral 301 denotes an image data reduction processing block, which includes a data reduction processing unit 302, a memory write control circuit 303, and an input timing signal generation circuit 304. A frame memory 305 stores image data. An image data enlargement processing block 306 includes a memory read control circuit 307, a data enlargement processing unit 308, and an output timing signal generation circuit 309.
[0030]
Reference numeral 401 denotes a horizontal write timing position start register, 402 denotes a horizontal write position end register, 403 denotes a vertical write position start register, and 404 denotes a vertical write position end register. It is possible to specify the writing range. Here, the registers 402 and 404 are registers for specifying the ends of the horizontal and vertical write positions, respectively. However, it is apparent that the registers 402 and 404 may be registers for specifying the horizontal and vertical write widths, respectively.
[0031]
405 is a horizontal read timing position start register, 406 is a horizontal read position end register, 407 is a vertical read position start register, 408 is a vertical read position end register, and is stored in the frame memory 305 of input image data according to each register setting. It is possible to specify the range from which the image data is read. Here, the registers 406 and 408 are registers for specifying the horizontal and vertical read position ends, respectively, but it is clear that they may be registers for specifying the horizontal and vertical read widths, respectively.
[0032]
Reference numeral 409 denotes a horizontal reduction / enlargement magnification setting register, and 410 denotes a vertical reduction / enlargement magnification setting register, which sets the magnification of the reduction or enlargement processing in the image data reduction processing block 301 and the image data enlargement processing block 306. If the reduction and enlargement magnifications are set to 1, the image data can be processed at the same magnification. Each of the register settings described above is performed via the control unit 204.
[0033]
Referring again to FIG. 1, reference numeral 207 denotes a DDC communication processing unit which performs DDC communication with the personal computer or another image display device when the personal computer 100 or another image display device 200 is connected. Reference numeral 206 denotes a rewritable memory for storing attribute information of the image display device based on EDID information specified by VESA (Video Electronics Standards Association).
[0034]
The DDC communication processing unit 207 enables the personal computer 100 to read EDID information stored in the memory 206 and output optimal image data to the image display device 200 by enabling communication between the personal computer 100 and the memory 206. Enables plug and display function. Further, in the image display device of the present embodiment, by enabling communication between the control unit 204 and the memory 206, the EDID information stored in the memory can be rewritten. Further, by enabling communication between the control unit 204 and another image display device connected to the input side or the output side of the image display device 200, the attribute information can be mutually obtained between the image display devices. I do. In the present embodiment, information regarding the resolution and the number of connected display devices is exchanged using DDC communication. Hereinafter, the DDC communication processing unit 207 will be described in more detail.
[0035]
As shown in FIG. 1, in the present embodiment, two (200-1, 200-2) image display devices according to the embodiment are connected. Here, the description will be focused on the first image display device 200-1. Hereinafter, the processing according to the present embodiment will be described in detail with reference to the flowchart shown in FIG.
[0036]
First, in step S100, the total number of connections Cti = 1, the number of output side connections Cdi = 0, the number of horizontal pixels Nh = Nh0, and the number of vertical pixels Nv = Nv0 are initialized. Here, Nh0 and Nv0 are the number of display pixels included in the image display device 200-1 alone, and in this embodiment, Nh0 = 800 and Nv0 = 600. Next, in step S101, it is determined whether or not the image display device 200-2 is connected on the output side of the image display device 200-1. This determination can be made by configuring the DDC communication terminal on the output side to be always kept in the High state by the pull-up resistor. That is, the DDC communication processing unit 207-1 opens a communication line between the control unit 204-1 and the image display device 200-2 connected to the output side, and the control unit 204-1 tries to communicate with the outside. If the acknowledgment is returned, it can be determined that the image display device 200-2 is connected to the output side. If it is determined that there is no connected image display device 200-2, the process proceeds to step S105.
[0037]
When it is determined that there is an image display device 200-2 to be connected, the process proceeds to step S102, and the number of output-side connections Chd, the total number of connections Cht, the number of horizontal pixels Nhd, and the number of vertical pixels in the image display device 200-2 as attribute information. Read the number Nvd. At this time, the DDC communication processing unit 207-1 opens a communication line with the image display device 200-2 connected to the output side, and is stored in the memory 206-2 of the connected image display device 200-2. Get these values from the information.
[0038]
Next, the process proceeds to step S103, and the respective attribute information of the image display device 200-1 is updated. Specifically, the output side connection number Cdi is updated to Chd + 1, the total connection number Cti is updated to Cht + 1, the horizontal pixel number Nh is updated to Nh + Nhd, and the vertical pixel number Nv is updated to Nv.
[0039]
Next, the process proceeds to step S104, where the DDC communication processing unit 207-1 opens a communication line between the control unit 204-1 and the memory 206-1 in response to a request from the control unit 204-1, and the control unit 204- No. 1 stores Cti = 2, Cdi = 1, Nh = 1600 (= Nh + Nhd = 800 + 800), and Nv = 600 in the memory 206-1 as updated information.
[0040]
Next, in step S105, the presence or absence of connection on the input side is determined. Here, the DDC communication processing unit 207-1 opens a communication line with the input side at the request of the control unit 204-1. The determination of the presence or absence of connection can be performed by the same means as the method of determining the presence or absence of connection on the output side. However, when viewed from the image display device connected to the input side, it is necessary to set to open the communication line of the DDC communication processing unit of the image display device to the output side. Therefore, a DDC communication request is made to the input side. This can be achieved, for example, by communication in which an address different from that specified in the DDC standard is assigned. When a personal computer is connected to the input side, communication cannot be performed by this method, so it can be determined that there is no connection on the input side. Here, if it is determined that there is no connection, the process ends without updating any information.
[0041]
On the other hand, if it is determined in step S105 that the image display device is connected, the process proceeds to step S106, and the total connection number information Ct stored in the memory of the image display device connected to the input side is acquired. Next, the process proceeds to step S107, in which the total connection number information Cti currently held by the image display device 200-1 is compared with the acquired total connection number information Ct. Here, if Cti ≧ Ct, the process ends. If Ct> Cti, the process proceeds to step S108, where Cti = Ct.
[0042]
Next, in step S109, the DDC communication processing unit 207-1 opens a communication line between the control unit 204-1 and the memory 206-1 in response to a request from the control unit 204-1. Cti is stored as the updated information in 206-1. By performing the processing from step S105 to step S109, the total connection number information Cti in all the connected image display devices is matched. Therefore, it is possible to determine the position of each image display device based on the output side connection number information Cdi and the total connection number information Cti updated in step S104.
[0043]
By sequentially performing the above processing for each connected image display device, for example, in the configuration shown in FIG. 1, the first image display device 200-1 has a horizontal pixel number (Nh) of 1600 and a vertical pixel number (Nv) of 600 And the number of connections on the output side (Cdi) is one, and the total number of connections (Cti) is two. The image display device 200-2 connected to the output side has a horizontal pixel number (Nh) of 800, a vertical pixel number (Nv) of 600, no output side connection (Cdi) (zero), and a total number of connections (Cti). It has information of two units. This is shown in FIG.
[0044]
When a personal computer is connected to the two connected image display devices as described above, the personal computer performs DDC communication with the first image display device 200-1, and the connected image display device has 1600 horizontal pixels and 1600 vertical pixels. It reads that it has a resolution of 600 and outputs a signal optimal for that resolution. In other words, it is possible to output an image signal having a resolution corresponding to the display resolution of the image display device.
[0045]
Hereinafter, the image display method according to the present embodiment will be described with an example in which the personal computer outputs an image signal having 1600 horizontal pixels and 600 vertical pixels in the configuration of FIG.
[0046]
FIG. 5 is a flowchart illustrating the image display method. FIG. 5 shows image display control in each image display device.
[0047]
First, in step S200, the total number of connections Cti, the number of connections on the output side Cdi, the number of unique horizontal pixels Nh0, and the number of unique vertical pixels Nv0 are acquired. Next, in step S201, it is determined whether or not Cti> 1. If Cti = 1, it means that the image display device exists alone, so this processing is terminated, and the image display is performed by a normal method as a single image display device. On the other hand, if Cti> 1, it is determined that one screen is configured by a plurality of image display devices, and the process proceeds to step S202.
[0048]
In step S202, the resolution (the number of horizontal pixels Nhi, the number of vertical pixels Nvi) of the input image signal is determined. As a method of determining the resolution, a known method used in a so-called multi-scan type image display device can be used. Next, the horizontal writing width is calculated in step S203. Here, the writing means writing to the frame memory 305 in FIG. The horizontal writing width Lh is a value obtained by dividing the number of horizontal pixels Nhi of the input image signal by the total number of connections Cti. This means that the images are equally displayed on each of the connected image display devices. Therefore, when Nhi = 1600 in a system in which two image display devices are connected as in the present embodiment, Cti = 2 and Lh = 800.
[0049]
Next, in step S204, a horizontal write start position is calculated. The horizontal write start position Whs is defined as Hbp in a period from the horizontal synchronization signal of the input image signal to the effective image signal.
Whs = Hbp + Lh × (Cti−Cdi−1)
Is calculated by
[0050]
In this example, since Cti = 2 and Cdi = 1 in the first image display device 200-1, the horizontal writing start position of the first image display device is Whs1 = Hbp. In the second image display device 200-2, Cti = 2 and Cdi = 0, so that Whs2 = Hbp + 800.
[0051]
Next, the horizontal write end position is calculated in step S205. The horizontal write end position Whe is a value obtained by adding the horizontal write width Lh to the horizontal write start position Whs.
[0052]
In this embodiment, since the connection in the vertical direction is not taken into account, the calculation of the writing width in the vertical direction and the start position are not performed again. Next, the process proceeds to step S206 to calculate the display magnification. The horizontal and vertical display magnifications can be calculated by Mh = Nh0 / Lh and Mv = Nv0 / Nvi, respectively. That is, it is the ratio of the width of the image signal written in the frame memory to the number of pixels provided in the image display device.
[0053]
By setting the write start position, the write end position, and the reduction / enlargement ratio calculated in the above-described processing in each register shown in FIG. 2, it is possible to perform an optimal image display.
[0054]
This is shown in FIG. In FIG. 6, an area indicated by 200-1 is displayed by the image display device 200-1, and an area indicated by 200-2 is displayed by the image display device 200-2. In the image display device 200-1, since Nh0 = 800, Mh = Nh0 / Lh = 800/800 = 1. Therefore, the resolution conversion unit 202-1 outputs the image data (800 × 600) written in the frame memory 305 without scaling.
[0055]
In the present embodiment, the flow in which the input image signal is horizontally and vertically enlarged and reduced in accordance with the image display area is described independently. There is no essential difference even if display is performed in accordance with one of the larger reduction ratio or the smaller expansion ratio.
[0056]
As described above, the attribute information is acquired between a plurality of image display devices connected to each other including the DDC communication control unit 207, and the result of calculating the total number of pixels is stored as EDID information. When viewed, it can be recognized as one image display device having high resolution. Further, based on the connection information between the image display devices, the image signals output from the personal computer can be autonomously displayed uniformly on a plurality of image display devices.
[0057]
<Second embodiment>
In the first embodiment, the configuration in which the display is connected in the horizontal direction has been described. In the second embodiment, a configuration in which displays are connected in the horizontal and vertical directions will be described.
[0058]
FIG. 7 is a block diagram illustrating the configuration of the image forming apparatus according to the second embodiment. In FIG. 7, blocks having the same functions as those in FIG. 1 are denoted by the same reference numerals. The main difference from the first embodiment is that a direction determining means 209 is provided. The direction determining unit 209 outputs a signal indicating whether the subsequent image display device is arranged in the horizontal direction or the vertical direction. The direction determining means 209 is, for example, a mechanical switch for setting a High or Low state, and when High, it is possible to determine a horizontal arrangement, and when Low, it is possible to determine a vertical arrangement.
[0059]
In this embodiment, it is assumed that nine image display devices are connected as shown in FIG. Hereinafter, the display control according to the second embodiment will be described in detail with reference to the flowchart shown in FIG.
[0060]
First, in step S300, the total number of horizontal connections Chti = 1, the number of output horizontal connections Chdi = 0, the total number of vertical connections Cvti = 1, the number of vertical connections Cvdi = 0, the number of horizontal pixels Nh = Nh0, and the number of vertical pixels Nv = Nv0. Here, Nh0 and Nv0 are the number of display pixels provided independently in the image display device 200-n, and in this embodiment, Nh0 = 800 and Nv0 = 600. Next, in step S301, it is determined whether or not the image display device 200- (n + 1) is connected on the output side of the image display device 200-n. Here, if it is determined that there is no connected image display device 200- (n + 1), the process proceeds to step S307.
[0061]
If it is determined that there is an image display device 200- (n + 1) to be connected, the process proceeds from step S301 to step S302, and the output side horizontal connection number Chd, horizontal The total number of connections Cht, the number of output side vertical connections Cvd, the total number of vertical connections Cvt, the number of horizontal pixels Nhd, and the number of vertical pixels Nvd are acquired. At this time, the DDC communication processing unit 207-n opens a communication line with the image display device 200- (n + 1) connected to the output side, and the memory 206- (n + 1) of the connected image display device 200- (n + 1). Get the information stored in).
[0062]
Next, the process proceeds to step S303, and it is determined whether the connected image display device 200- (n + 1) is arranged in the horizontal direction or the vertical direction. This determination can be made by looking at the setting of the direction determining means 209-n. Here, if it is determined that they are arranged in the horizontal direction, the process proceeds to step S304, and the attribute information of the image display device 200-n is updated. Specifically, the number of output horizontal connections Chdi = Chd + 1, the total number of horizontal connections Chti = Cht + 1, the number of output vertical connections Cvdi = Cvd, the total number of vertical connections Cvti = Cvt, the number of horizontal pixels Nh = Nh + Nhd, and the number of vertical pixels Nv = Nv, and the process proceeds to the next step S306.
[0063]
If it is determined in step S303 that they are arranged in the vertical direction, the process advances to step S305 to update the attribute information of the image display device 200-n. Specifically, the output side vertical connection number Cvdi = Cvd + 1, the vertical total connection number Cvti = Cvt + 1, the horizontal pixel number Nh = Nh, and the vertical pixel number Nv = Nv + Nvd, and the process proceeds to the next step S306.
[0064]
In step S306, the DDC communication processing unit 207-n opens a communication line between the control unit 204-n and the memory 206-n in response to a request from the control unit 204-n, and returns to the memory 206-n in step S304 or S305. The updated Chti, Chdi, Cvti, Cvdi, Nh, and Nv are stored.
[0065]
Next, in step S307, the presence or absence of connection on the input side is determined. Here, the DDC communication processing unit 207-n opens a communication line with the input side at the request of the control unit 204-n. Here, if it is determined that there is no connection, the process ends without updating any information. If it is determined that there is a connection, the process proceeds to step S308, and the horizontal total connection number information stored in the memory 206- (n-1) of the image display device 200- (n-1) connected to the input side Cht and vertical total connection number information Cvt are acquired. Next, the process proceeds to step S309 to compare the horizontal total connection number information Chti currently held by the image display device 200-n with the acquired horizontal total connection number information Cht. Here, if Chti = Cht, the process proceeds to step S311. If Cht> Chti, the process proceeds to step S310 to update Chti with the value of Cht.
[0066]
Next, the process proceeds to step S311 to compare the vertical total connection number information Cvti currently possessed by the image display device 200-n with the acquired vertical total connection number information Cvt. Here, if Cvti = Cvt, the process proceeds to step S313. If Cvt> Cvti, the process advances to step S312 to update Cvti with the value of Cvt.
[0067]
Next, the process proceeds to step S313. The DDC communication processing unit 207-n opens a communication line between the control unit 204-n and the memory 206-n at the request of the control unit 204-n, and the control unit 204-n is updated to the memory 206-n. The stored Chti and Cvti are stored.
[0068]
By performing the processing from step S307 to step S313, the total horizontal connection number information Chti and the total vertical connection information Cvti in all the connected image display devices are made to match. Therefore, the image display devices are arranged in any position based on the output side horizontal connection number information Chdi, the output side vertical connection number information Cvdi, the total horizontal connection number information Chti, and the total vertical connection information Cvti updated in step S330. Can be determined.
[0069]
The above-described flow is sequentially performed for each connected image display device. For example, when the image display devices of Nh0 = 800 and Nv0 = 600 are arranged as shown in FIG. Has the number of horizontal pixels (Nh) of 2400 and the number of vertical pixels (Nv) of 1800, and has information of three total horizontal connections (Chti) and three total vertical connections (Cvti). The information possessed by each of the other image display devices is as shown in FIG.
[0070]
When a personal computer is connected to the image display device connected as shown in FIG. 8, the personal computer performs DDC communication with the first image display device 200-1, and the connected image display device has 2400 horizontal pixels and vertical pixels. It is possible to read that a resolution of several 1800 is provided, and to output a signal optimal for the resolution. For example, assuming that the personal computer has output a QXGA image signal having 2048 horizontal pixels and 1536 vertical pixels, an image display method will be described next.
[0071]
FIG. 10 is a flowchart illustrating an image display method according to the second embodiment. First, in step S400, the total number of horizontal connections Chti, the number of output horizontal connections Chdi, the total number of vertical connections Cvti, the number of output vertical connections Cvdi, the number of unique horizontal pixels Nh0, and the number of unique vertical pixels Nv0 are acquired. Next, in step S401, it is determined whether or not Chti × Cvti> 1. If Chti × Cvti = 1, it means that the image display device exists alone, so the processing is terminated, and the image display is performed by a normal method as a single image display device. On the other hand, if Chti × Cvti> 1, it is determined that a plurality of image display devices constitute one screen, and the process proceeds to step S402.
[0072]
In step S402, the resolution (the number of horizontal pixels Nhi, the number of vertical pixels Nvi) of the input image signal is determined. As a determination method, a known method used in a so-called multi-scan type image display device can be used. Next, the horizontal writing width is calculated in step S403. Here, "writing" means writing to the frame memory 305 in FIG. The horizontal writing width Lh is a value obtained by dividing the number of horizontal pixels Nhi of the input image signal by the total number of horizontal connections Chti. Next, a vertical writing width is calculated in step S1301. The vertical writing width Lv is a value obtained by dividing the number of vertical pixels Nvi of the input image signal by the total number of vertical connections Cvti. This means that the images are equally displayed on each of the connected image display devices. Therefore, in the case of a system in which nine image display devices are connected as in the present embodiment, Nh = 2048, Nvi = 1536, Chti = 3, Cvti = 3, and Lh = 683 and Lv = 512.
[0073]
Next, in step S405, the horizontal write start position Whs is calculated. The horizontal write start position Whs is calculated by Whs = Hbp + Lh × (Chti−Chdi−1), where Hbp is the period from the horizontal synchronization signal of the input image signal to the effective image signal. Here, the first image display devices (200-4, 200-7) arranged in the horizontal direction including the first image display device 200-1 have Chti = 3 and Chdi = 2, and therefore Whs1 = Hbp. Become. In the second image display devices 200-2, 5, and 8 arranged in the horizontal direction, Chti = 3 and Chdi = 1, so Whs2 = Hbp + 683, and the third image display devices 200-3, 6, and 9 Since Chti = 3 and Chdi = 0, Whs3 = Hbp + 1366.
[0074]
Next, in step S406, the horizontal write end position Whe is calculated. The horizontal write end position Whe is a value obtained by adding the horizontal write width Lh to the horizontal write start position Whs, that is, Whe = Whs + Lh.
[0075]
Next, in step S407, the vertical write start position Wvs is calculated. The vertical write start position Wvs is calculated as Wvs = Vbp + Lv × (Cvti−Cvdi−1), where Vbp is the period from the vertical synchronization signal of the input image signal to the effective image signal. Here, the first image display devices (200-1 to 200-3) arranged in the vertical direction including the first image display device 200-1 have Wvs1 = Vbp because Cvti = 3 and Cvdi = 2. . The second vertically arranged image display devices 200-4 to 200-6 have Cvti = 3 and Cvdi = 1, so Wvs4 = Vbp + 512, and the third vertically arranged image display device 200-7. 9 are Cvti = 3 and Cvdi = 0, so that Wvs2 = Vbp + 1024.
[0076]
Next, a vertical write end position is calculated in step S408. The vertical write end position Wve is a value obtained by adding the vertical write width Lv to the vertical write start position Wvs.
[0077]
Next, the process proceeds to step S409 to calculate a display magnification. The horizontal and vertical display magnifications can be calculated by Mh = Nh0 / Lh and Mv = Nv0 / Lv, respectively. That is, it is the ratio of the width of the image signal written in the frame memory to the number of pixels provided in the image display device. In the above example, Mh = 800/683 = 1.17 and Mv = 600/512 = 1.17. This is shown in FIG.
[0078]
In the present embodiment, the flow in which the input image signal is horizontally and vertically enlarged and reduced in accordance with the image display area is described independently. There is no essential difference even if display is performed in accordance with one of the larger reduction ratio or the smaller expansion ratio.
[0079]
As described above, the attribute information is obtained between a plurality of image display devices connected with the DDC communication control unit 207, and the total pixel count is calculated and stored as EDID information. When viewed, it can be recognized as one image display device having high resolution. Further, based on the connection information between the image display devices, the image signals output from the personal computer can be displayed evenly on a plurality of image display devices autonomously.
[0080]
In each of the above embodiments, each image forming apparatus automatically acquires Chti, Chdi, Cvti, and Cvdi by communicating with devices connected before and after. And Chit, Chdi, Cvti, and Cvdi may be directly set by the user. In this case, the process of accumulating only the resolution may be performed by the DDC communication.
[0081]
【The invention's effect】
As described above, according to the present invention, a multi-display system can be realized at low cost by using an image display device that can be used alone as a normal independent image display device.
[0082]
Further, according to the present invention, a multi-display system can be autonomously configured by simply connecting a plurality of image display devices without requiring a control device for image display separately from the image display devices.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration example of an image display device according to a first embodiment.
FIG. 2 is a block diagram illustrating a detailed configuration example of a resolution conversion unit according to the first embodiment.
FIG. 3 is a flowchart illustrating a setting process of attribute information of the image display device according to the first embodiment.
FIG. 4 is a diagram showing attribute information of the image display device according to the first embodiment.
FIG. 5 is a flowchart illustrating display control of the image display device according to the first embodiment.
FIG. 6 is a conceptual diagram of register setting of an image signal according to the first embodiment.
FIG. 7 is a block diagram illustrating a configuration example of an image display device according to a second embodiment.
FIG. 8 is a diagram showing connection status and attribute information of each image display device according to the second embodiment.
FIG. 9 is a flowchart illustrating a setting process of attribute information of the image display device according to the second embodiment.
FIG. 10 is a flowchart illustrating display control of an image display device according to a second embodiment.
FIG. 11 is a conceptual diagram of register setting of an image signal according to a second embodiment.
FIG. 12 is a block diagram illustrating a configuration of a general image display device.
FIG. 13 is a block diagram illustrating a configuration of a general image display device that can configure a multi-display system.

Claims (17)

An image display device having an image display unit,
Input / output means for inputting image data from a device connected on the upstream side and outputting the image data to a device connected on the downstream side,
When a display device is connected to the downstream side, an obtaining unit that obtains resolution information from the display device,
Generating means for generating resolution information based on the resolution information obtained by the obtaining means and the resolution of the image display unit,
An image display device comprising: a first holding unit that holds the generated resolution information so as to be notified to an upstream side. The image display device according to claim 1, further comprising a determination unit configured to determine whether a display device is connected on a downstream side. Communication processing means for performing DDC communication with an external device;
A memory for storing EDID information communicated by the DDC communication,
The obtaining means obtains resolution information using the communication processing means,
2. The image display apparatus according to claim 1, wherein the holding unit rewrites the generated resolution information as a corresponding item of EDID information in the memory. The apparatus further includes a direction determination unit that determines whether the downstream device is arranged in the vertical direction or the horizontal direction,
2. The image processing apparatus according to claim 1, wherein the generation unit accumulates the resolution in the direction determined by the direction determination unit with respect to the resolution information acquired by the acquisition unit and the resolution of the image display unit, and generates the resolution information. 3. The image display device according to 1. When a display device is connected to at least one of the upstream side and the downstream side, determining means for determining the position of the display device in a multi-display formed by all connected display devices,
Determining means for determining an image range to be displayed by the image display unit based on the position determined by the determining means;
2. The image display device according to claim 1, further comprising: a display control unit configured to display, on the image display unit, an image range determined by the determination unit from the image data input by the input / output unit. The display control unit sets a display magnification based on the number of pixels in the image range and a resolution of the image display unit, and performs resolution conversion on an image in the image range based on the display magnification. The image display device according to claim 5, wherein the image is displayed on an image display unit. The determining means includes:
When a display device is connected to the downstream side, it obtains chain information indicating a chain state of the devices on the downstream side of the display device, generates chain information of the device based on this, and can notify the upstream side. Second holding means for holding the
When a display device is connected to the upstream side, a third holding unit that acquires the total number of devices indicating the total number of connected display devices from the display device on the upstream side, and holds the total number of display devices to the downstream side so that notification is possible. ,
The image display device according to claim 5, wherein a position of the display device on a multi-display is determined based on the chain information and the total number of devices. The apparatus further includes a direction determination unit that determines whether the downstream device is arranged in the vertical direction or the horizontal direction,
The image display device according to claim 7, wherein the chain information includes information obtained by individually accumulating the number of chains in a vertical direction and a horizontal direction. A multi-display system, wherein the image display device according to any one of claims 1 to 8 is connected, and a host computer is connected upstream of the most upstream image display device. A method for controlling an image display device having an image display unit,
An input / output step of inputting image data from a device connected on the upstream side and outputting the image data to a device connected on the downstream side,
When a display device is connected to the downstream side, an obtaining step of obtaining resolution information from the display device,
A generation step of generating resolution information based on the resolution information obtained in the obtaining step and the resolution of the image display unit,
A first storing step of storing the generated resolution information in a memory so that the generated resolution information can be notified to an upstream side. The image display method according to claim 10, further comprising a determination step of determining whether a display device is connected to a downstream side. The image display device includes a communication processing unit that performs DDC communication with an external device, and a memory that stores EDID information communicated by the DDC communication,
The obtaining step obtains resolution information via the communication processing unit,
The image display method according to claim 10, wherein the holding step rewrites the generated resolution information with a corresponding item of EDID information stored in the memory. The apparatus further includes a direction determination step of determining whether the downstream device is arranged vertically or horizontally.
The method according to claim 1, wherein, in the generating step, the resolution information is generated by accumulating the resolution in the direction determined in the direction determining step with respect to the resolution information acquired in the acquiring step and the resolution of the image display unit. The image display method described in 1. When a display device is connected to at least one of the upstream side and the downstream side, a determining step of determining the position of the display device in a multi-display formed by all connected display devices,
A determining step of determining an image range to be displayed by the image display unit based on the position determined in the determining step;
The image display method according to claim 10, further comprising a display control step of displaying, on the image display unit, an image range determined in the determination step from the image data input in the input / output step. The display control step sets a display magnification based on the number of pixels in the image range and a resolution of the image display unit, and converts an image in the image range into a resolution based on the display magnification. The image display method according to claim 14, wherein the image is displayed on an image display unit. The determining step includes:
When a display device is connected to the downstream side, it obtains chain information indicating a chain state of the devices on the downstream side of the display device, generates chain information of the device based on this, and can notify the upstream side. A second holding step of holding the
When a display device is connected to the upstream side, a third holding step of acquiring the total number of devices indicating the total number of connected display devices from the display device on the upstream side and holding the total number of display devices to the downstream side so as to be notified to the downstream side. ,
15. The image display method according to claim 14, wherein a position of the display device on a multi-display is determined based on the chain information and the total number of devices. The apparatus further includes a direction determination step of determining whether the downstream device is arranged vertically or horizontally.
17. The image display method according to claim 16, wherein the chain information includes information obtained by individually accumulating the number of chains in the vertical direction and the horizontal direction.

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